KR102196507B1 - Apparatus for visible light communication using electrically switchable glass and method using same - Google Patents

Abstract

A visible light communication device and method using electrically switchable glass are disclosed. A visible light communication device using electrically switchable glass according to an embodiment of the present invention comprises: a receiving unit for receiving a data signal; A control unit for generating a current and voltage corresponding to the data signal and controlling the transmittance of the electrically switchable glass based on the current and voltage; And a transmitter configured to adjust the brightness of visible light passing through the glass based on the transmittance, and perform visible light communication using the visible light passing through the glass.

Description

Visible light communication device and method using electrically switchable glass {APPARATUS FOR VISIBLE LIGHT COMMUNICATION USING ELECTRICALLY SWITCHABLE GLASS AND METHOD USING SAME}

The present invention relates to a technology for performing visible light communication, and more particularly, to a technology for performing visible light communication using a conventional light source that cannot perform visible light communication and glass that can be electrically switched.

Conventional visible light communication transmits data to the lighting output by directly applying a modulated signal to a light source, so only a device including a light source capable of visible light wireless communication must be used. There is a problem.

In simple lighting that illuminates the dark, visible light wireless communication is not possible, and lighting devices including various light source sources that are conventionally used that do not have a built-in visible light wireless communication function (fluorescent lamp, incandescent lamp, LED lamp, OLED , Metal highlight, etc.) Visible light wireless communication is not possible.

Electrically switchable glass is a glass that adjusts brightness by changing the transmission of light transmitted through the glass when a voltage is applied. Such glass is commonly known as a smart window or smart glass. These devices use electrochromic glass, suspended particle device glass, and PDLC glass (Polymer Dispersed Liquid Crystal glass) as typical examples, but they can be applied in various ways. It is not limited.

In addition, it is not limited to the material of glass, including the case of attaching synthetic resins to the glass, and a material that adjusts the brightness by changing the amount of light transmitted when a voltage is applied is also included in smart glass.

These smart glasses are used for controlling the amount of light transmitted from an external light source, and thus there is a problem in that visible light wireless communication is not possible.

Korean Patent Publication No. 2013-0101617 discloses a technology for providing additional information from a server to a visible light communication terminal through visible light communication.

However, Korean Patent Publication No. 2013-0101617 is a light source capable of performing ON/OFF with a specific frequency so that a light source that outputs visible light can perform visible light communication in performing visible light communication. As a technology using the technology, the technology for performing visible light communication using an existing light source that cannot perform visible light communication is silent.

Therefore, in view of the recent trend of increasing importance of visible light communication and the problem that the light source capable of performing visible light communication is relatively expensive compared to the existing light source, a technology capable of performing visible light communication while using the existing light source. The necessity of this is emerging.

An object of the present invention is to easily adjust the brightness of visible light to facilitate visible light communication.

In addition, an object of the present invention is to perform visible light communication while using an existing light source that cannot perform visible light communication as it is.

In addition, an object of the present invention is to reduce the cost of installing a visible light communication facility by using an existing light source that cannot perform visible light communication as it is.

A visible light communication device using an electrically switchable glass for achieving the above object comprises: a receiving unit for receiving a data signal; A control unit for generating a current and voltage corresponding to the data signal and controlling the transmittance of the electrically switchable glass based on the current and voltage; And a transmitter configured to adjust the brightness of visible light passing through the glass based on the transmittance, and perform visible light communication using the visible light passing through the glass.

In this case, the control unit comprises: a code data generator configured to generate code data by converting the data signal based on a preset rule; A modulator that modulates the code data to generate a transmission signal corresponding to the data signal; And a switchable circuit unit controlling the flow of current and voltage corresponding to the transmission signal by performing switching based on the transmission signal.

In this case, the transmittance of the electrically switchable glass may be controlled based on changes in current and voltage within the switching circuit.

In this case, the switchable circuit unit performs switching based on the transmission signal, and as a result of the execution, it may be in any one of a digital logic 0 state and a digital logic 1 state.

In this case, the electrically switchable glass may have the lowest transmittance in the digital logic 0 state, and the transmittance may be the highest in the digital logic 1 state.

In this case, the electrically switchable glass may have the highest transmittance when in the digital logic 0 state and the lowest transmittance when in the digital logic 1 state.

In this case, the control unit may further include a power control unit for transferring power to the electrically switchable glass, the code data generation unit, the modulator, and the switchable circuit unit.

At this time, the switchable circuit unit may enter the digital logic 0 state when the bit inside the transmission signal is 0, and enter the digital logic 1 state when the bit inside the transmission signal is 1.

At this time, the switching circuit unit may enter the digital logic 0 state when the bit inside the transmission signal is 1, and enter the digital logic 1 state when the bit inside the transmission signal is 0.

In addition, the visible light communication method using the electrically switchable glass according to an embodiment of the present invention comprises the steps of receiving a data signal; Generating a current and voltage corresponding to the data signal, and controlling the transmittance of the electrically switchable glass based on the current and voltage; And adjusting the brightness of visible light passing through the glass based on the transmittance, and performing visible light communication using the visible light passing through the glass.

In this case, controlling the transmittance may include converting the data signal based on a preset rule to generate code data; Generating a transmission signal corresponding to the data signal by modulating the code data; And controlling, by a switchable circuit unit, a current and voltage flow corresponding to the transmission signal by performing switching based on the transmission signal.

In this case, the transmittance of the electrically switchable glass may be controlled based on whether current and voltage change in the switchable circuit unit.

In this case, in the controlling of the flow of the current, switching is performed based on the inside of the transmission signal, and as a result of the execution, the switchable circuit unit may be in any one of a digital logic 0 state and a digital logic 1 state. .

In this case, the electrically switchable glass may have the lowest transmittance in the digital logic 0 state, and the transmittance may be the highest in the digital logic 1 state.

In this case, the electrically switchable glass may have the highest transmittance when in the digital logic 0 state and the lowest transmittance in the digital logic 1 state.

In this case, controlling the flow of the current corresponding to the transmission signal is when the bit inside the transmission signal is 0, the state of the switchable circuit unit becomes the digital logic 0 state, and the bit inside the transmission signal When is 1, the state of the switchable circuit unit may be the digital logic 1 state.

In this case, controlling the flow of the current corresponding to the transmission signal is when the bit in the transmission signal is 0, the switchable circuit unit is in the digital logic 1 state, and the bit in the transmission signal is 1 When, the switchable circuit unit may enter the digital logic 0 state.

In the present invention, since the brightness of visible light can be controlled together with a communication signal by using an electrically switchable glass, visible light communication can be easily performed.

In addition, the present invention can perform visible light communication while using an existing light source that cannot perform visible light communication.

In addition, according to the present invention, an existing light source that cannot perform visible light communication can be used as it is, so that the cost of installing visible light communication facilities can be reduced.

1 to 2 are diagrams showing the principle of performing visible light communication using electrically switchable glass.
3 is a block diagram showing a visible light communication device using an electrically switchable glass according to an embodiment of the present invention.
4 is a block diagram showing an embodiment of the control unit shown in FIG. 3.
5 is a block diagram showing a visible light communication device using an electrically switchable glass according to another embodiment of the present invention.
6 to 7 are diagrams illustrating performing visible light communication using a visible light communication device using electrically switchable glass according to an embodiment of the present invention.
8 is a flowchart illustrating a visible light communication method using an electrically switchable glass according to an embodiment of the present invention.

The present invention will be described in detail with reference to the accompanying drawings as follows. Here, repeated descriptions, well-known functions that may unnecessarily obscure the subject matter of the present invention, and detailed descriptions of configurations are omitted. Embodiments of the present invention are provided to more completely explain the present invention to those with average knowledge in the art. Accordingly, the shapes and sizes of elements in the drawings may be exaggerated for clearer explanation.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 to 2 are diagrams showing the principle of performing visible light communication using electrically switchable glass.

First, visible light output from a light source passes through an electrically switchable glass, reaches a photo detector, and performs an operation in the light receiver, so that data can be received. In visible light communication, when light arrives, it is determined that digital signal 1 is received, and when light does not arrive, it is determined that digital signal 0 is received. For example, in order to transmit 1001 information, the light source can be adjusted in such a way that the light does not arrive after the light arrives and then the light arrives again.

In this case, there may be a method of performing visible light communication by appropriately repeatedly turning on or off the light source. However, this method has a problem in that a device for automatically performing on or off must be inserted inside the light source.

At this time, light is continuously output from the light source, and the light passes through to reach the receiver (corresponding to digital signal 1), or does not allow light to pass through and does not reach the receiver (corresponding to digital signal 0). There is a method of performing visible light communication by using. The present invention can perform visible light communication using this method. Therefore, the present invention has the advantage of using an existing light source as it is.

Referring to FIG. 1, when a switchable circuit unit 110 exists, and a digital signal 0 reaches the circuit unit 110, it is switched to an open state, so that a voltage is not transmitted to the glass. .

In this case, the electrically switchable glass may block visible light passing through when no voltage is transmitted. Thus, visible light may not be transmitted to the photo detector, which corresponds to digital signal 0.

Referring to FIG. 2, when there is a switchable circuit unit 210 as in FIG. 1, and when digital signal 1 is transmitted to the circuit unit 210, the voltage is transferred to the glass by switching to a short state. Can be adjusted to be

In this case, the electrically switchable glass can pass visible light when a voltage is transmitted. Thus, visible light can be transmitted to the photo detector, which corresponds to digital signal 1.

In FIGS. 1 to 2, for convenience of understanding, digital signals 0 or 1 are distinguished based on whether or not visible light is transmitted to a photo detector, but when a threshold is set and visible light having a brightness exceeding the threshold is received, It may be determined that digital signal 1 has been received, and when visible light less than a threshold value is received, it may be determined that digital signal 0 has been received.

3 is a block diagram showing a visible light communication device using an electrically switchable glass according to an embodiment of the present invention.

Referring to FIG. 3, a visible light communication device using electrically switchable glass according to an embodiment of the present invention includes a receiving unit 310, a control unit 320, and a transmitting unit 330.

The receiving unit 310 performs communication and receives a data signal to be transmitted.

The control unit 320 generates a current and a voltage corresponding to the data signal, and the current

And controlling the transmittance of the electrically switchable glass based on the voltage.

In this case, the controller 320 may convert a data signal to generate a transmission signal, and may control the transmittance of the electrically switchable glass using the transmission signal.

In this case, the transmittance of the electrically switchable glass may be controlled based on changes in current and voltage by performing switching using a switchable circuit unit.

For example, when the data signal 1 is transmitted to the switchable circuit unit, the digital signal 0 may be in the state, and when the data signal 0 is transmitted, the digital signal 1 may be in the state. Accordingly, whether a current flows through the switchable circuit unit may be determined according to whether the data signal is 1 or 0, and the transmittance of the electrically switchable glass may be changed according to whether a current flows through the switchable circuit unit.

Further, for example, when the data signal 0 is transmitted to the switchable circuit unit, the digital signal 0 may be in the state, and when the data signal 1 is transmitted, the digital signal 1 may be in the state. Accordingly, whether a current flows through the switchable arc unit may be determined depending on whether the data signal is 1 or 0, and the transmittance of the electrically switchable glass may change depending on whether a current flows through the switchable circuit unit.

In this case, the state of the digital signal 0 may mean transmitting visible light having a lower illuminance than the state of the digital signal 1. For example, the digital signal 0 state means a state in which all visible light is blocked and visible light cannot be received, and the digital signal 1 state means a state in which all visible light is transmitted and visible light is received.

Also, for example, the digital signal 0 state means a state in which visible light can be transmitted below a specific threshold, and the digital signal 1 state means a state in which visible light can be transmitted above a specific threshold.

At this time, the control unit 320 may control the transmittance of the glass in consideration of the surrounding brightness. For example, when the surroundings are bright due to a light source output from other light sources, when transmitting the data signal 1, the transmittance may be made larger than before to increase the intensity of visible light used for performing visible light communication. In addition, for example, when the surroundings are dark, when transmitting the data signal 0, the transmittance may be made smaller than that of the existing one, so that the intensity of visible light used to perform visible light communication may be lowered. This is because when the surroundings are dark, there is no problem in performing visible light communication even if the intensity of visible light is lowered. Rather, if the intensity of visible light is not lowered, it may cause discomfort to people's eyes, so it may be more desirable to lower the intensity of visible light.

The transmitter 330 adjusts the brightness of visible light passing through the glass based on the transmittance, and performs visible light communication using the visible light passing through the glass.

In this case, the meaning of controlling the brightness of visible light based on the transmittance means that the more visible light passes, the brighter the visible light becomes, and the more visible light does not pass, the darker the brightness of the visible light.

At this time, when there is visible light passing through the glass, the receiver that receives visible light generates digital signal 1, and when there is no visible light that has passed through the glass, the receiver that does not receive visible light generates digital signal 0 Visible light communication can be performed by using the method.

FIG. 4 is a block diagram showing an embodiment of the controller 320 shown in FIG. 3.

Referring to FIG. 4, the control unit 320 includes a code data generation unit 410, a modulator 420, and a switchable circuit unit 430.

The code data generator 410 generates code data by converting the data signal based on a preset rule.

In this case, the code data may mean data to be transmitted by processing data signals.

At this time, there are no restrictions on the preset rules. The encoding rules used in the communication field may be used as they are.

The modulator 420 modulates the code data to generate a transmission signal corresponding to the data signal.

At this time, there is no limitation on the modulation method. OOK (On-Off Keying), ASK (Amplitude Shift Keying), FSK (Frequency Shift Keying), PSK (Phase Shift Keying) CDMA (Code Division Multiple Access), OFDM (Orthogonal frequency-division multiplexing) used in conventional digital communication A transmission signal can be generated by modulating code data using a modulation method such as.

The switchable circuit unit 430 controls the flow of current and voltage corresponding to the transmission signal by performing switching based on the transmission signal.

In this case, when the current and voltage change, the transmittance of the electrically switchable glass increases, and when the current and voltage do not change, the transmittance may decrease. Conversely, in the case of electrically switchable glass, the transmittance may decrease when the current and voltage change, and the transmittance may increase when the current and voltage do not change. Accordingly, the switchable circuit unit 430 can control the transmittance of the electrically switchable glass by controlling changes in current and voltage.

For example, when the data signal 1 is transmitted to the switchable circuit unit, the digital signal 0 may be in the state, and when the data signal 0 is transmitted, the digital signal 1 may be in the state. Accordingly, whether a current flows through the switchable circuit unit may be determined according to whether the data signal is 1 or 0, and the transmittance of the electrically switchable glass may be changed according to whether a current flows through the switchable circuit unit.

Further, for example, when the data signal 0 is transmitted to the switchable circuit unit, the digital signal 0 may be in the state, and when the data signal 1 is transmitted, the digital signal 1 may be in the state. Accordingly, whether a current flows through the switchable arc unit may be determined depending on whether the data signal is 1 or 0, and the transmittance of the electrically switchable glass may change depending on whether a current flows through the switchable circuit unit.

The method described in FIGS. 3 to 4 will be described again as follows by taking an example of transmitting the data signal 1010.

First, the data signal 1010 is received by the receiving unit 310.

At this time, the controller 320 generates a current and voltage corresponding to the data signal 1010, and controls the transmittance of the electrically switchable glass based on the current and voltage.

When this part is described in detail, first, in the case of 1, the control unit 320 controls the switchable circuit unit 430 to be in a short state, and current and voltage may change in the electrically switchable glass. In this case, the transmission unit 330 may allow visible light approaching toward the glass to pass through because the transmittance of the glass is increased, and may allow visible light to reach the light receiver. At this time, since the light receiver has received visible light, it receives information of 1.

Then, in the case of 0, the control unit 330 controls the switchable circuit unit 430 to be in an open state, and the current and voltage do not change in the electrically switchable glass. In this case, the transmission unit 320 may block visible light approaching the glass because the transmittance of the glass is lowered, and may prevent visible light from reaching the light receiver. At this time, since the light receiver has not received visible light, it receives information of 0.

Then, in case 1, the control unit 320 controls the switchable circuit unit 430 to be in a short state, and current and voltage may change in the electrically switchable glass. In this case, the transmission unit 330 may allow visible light approaching toward the glass to pass through because the transmittance of the glass is increased, and may allow visible light to reach the light receiver. At this time, since the light receiver has received visible light, it receives information of 1.

Then, in the case of 0, the control unit 330 controls the switchable circuit unit 430 to be in an open state, and the current and voltage do not change in the electrically switchable glass. In this case, the transmission unit 320 may block visible light approaching the glass because the transmittance of the glass is lowered, and may prevent visible light from reaching the light receiver. At this time, since the light receiver has not received visible light, it receives information of 0.

As a result, it is possible to transmit the data signal 1010 using a visible light communication device using electrically switchable glass, and receive the same data signal 1010 from the light receiver.

5 is a block diagram showing a visible light communication device using an electrically switchable glass according to another embodiment of the present invention.

Referring to FIG. 5, a visible light communication device using an electrically switchable glass includes a receiving unit 510, a control unit 520, and an electrically switchable glass 530.

In this case, the control unit 520 may include a power supply unit 521, a controller 522, a code data generation unit 523, a modulator 524, and a switchable circuit unit 525.

In this case, the control unit 520 may interlock with the electrically switchable glass 530.

At this time, the receiving unit 510 receives data for transmission. At this time, the data is not limited. For example, identification code (ID) data, text data, audio data, or image data may be applicable.

At this time, the power supply unit 521 supplies power required to perform communication to the controller 522. The controller 522 may supply power received from the power supply unit 521 to the code data generation unit 523, the modulator 524, and the switchable circuit unit 525.

In this case, the controller 522 may receive data from the receiving unit 510 and transmit the data to the code data generating unit 523 and control the data. For example, when the amount of received data exceeds the amount of data that can be transmitted, control is performed using a method of temporarily storing a part of the data and transmitting only the rest to the code data generator 523. You may.

In this case, the code data generation unit 523 may process the data received from the controller 522 and transmit it to the modulator 524.

At this time, there is no limitation on the method of generating code data. For example, it is possible to use an existing encoding method as it is during communication.

At this time, the modulator 524 modulates the code data received from the code data generator 523 to generate a transmission signal.

In this case, there is no limitation on a method of modulating the code data in the modulator 524. OOK (On-Off Keying), ASK (Amplitude Shift Keying), FSK (Frequency Shift Keying), PSK (Phase Shift Keying) CDMA (Code Division Multiple Access), OFDM (Orthogonal frequency-division multiplexing) used in conventional digital communication A transmission signal can be generated by modulating code data using a modulation method such as.

The switchable circuit unit 525 performs switching based on the transmission signal to control the flow of current and voltage corresponding to the transmission signal. In addition, the switchable circuit unit 525 may supply power to the electrically switchable glass 530.

In this case, when the electric switchable glass 530 changes, the transmittance increases when the current and the voltage change, and when the current and the voltage do not change, the transmittance may decrease. Conversely, in the electrically switchable glass 530, the transmittance may decrease when the current and voltage change, and the transmittance may increase when the current and voltage do not change. Accordingly, the switchable circuit unit 525 can control the transmittance of the electrically switchable glass by controlling changes in current and voltage.

For example, when the data signal 1 is transmitted to the switchable circuit unit 525, it may be in an open state, and when the data signal 0 is transmitted, it may be in a short state. Accordingly, whether a current flows through the switchable circuit unit 525 may be determined according to whether the data signal is 1 or 0, and the glass that can be electrically switched according to changes in current and voltage in the switchable circuit unit 525 ( The transmittance of 530) may vary.

Further, for example, when the data signal 0 is transmitted to the switchable circuit unit 525, it may be in an open state, and when the data signal 1 is transmitted, it may be in a short state. Accordingly, whether or not current flows through the switchable circuit unit may be determined according to whether the data signal is 1 or 0, and the switchable circuit unit 525 may be electrically switched according to the change in current and voltage. The transmittance can be varied.

The electrically switchable glass 530 illustrated in FIG. 5 has been described on the assumption that the transmittance increases when the current and voltage changes, and the transmittance decreases when the current and voltage do not change, but the present invention is not limited thereto. On the contrary, it is clear to those skilled in the art that the electrically switchable glass 530 can be applied to glass in which the transmittance is lowered when the current and voltage change, and the transmittance is increased when the current and voltage do not change.

The present invention described in FIG. 5 is not limited to a light source. Since it receives data signals such as incandescent bulbs, fluorescent lamps, and LED bulbs that were used in the past, and cannot determine on or off based on the data signal, it can be applied to light sources that have not been able to perform visible light communication. This is because the present invention can control the brightness of visible light output from a light source using electrically switchable glass.

6 to 7 are diagrams illustrating performing visible light communication using a visible light communication device using electrically switchable glass according to an embodiment of the present invention.

FIG. 6 is a diagram showing a visible light communication using a conventional light source and a visible light communication device using an electrically switchable glass according to an embodiment of the present invention. Referring to FIG. 6, a view using an electrically switchable glass A visible light communication device and a light source 620 and a light receiver 660 are shown.

A visible light communication device using electrically switchable glass includes a power control unit 610, power lines 611 and 612, an electrically switchable glass 630, and a control unit 640.

The power control unit 610 receives power through the power line 611 and supplies power to the control unit 640 using the power line 612.

At this time, the visible light output from the light source 620 reaches the electrically switchable glass 630, and the brightness is adjusted based on the transmittance controlled by the visible light communication device using the electrically switchable glass of the present invention and the modulated signal ( 630).

In this case, the light receiver 660 may receive the modulated signal 630 and demodulate it to receive data.

In this case, there is no limitation on the type of the light source 620. Since it receives data signals such as incandescent bulbs, fluorescent lamps, and LED bulbs that were used in the past, and cannot determine on or off based on the data signal, it can be applied to light sources that have not been able to perform visible light communication. This is because the present invention can control the brightness of visible light output from a light source using electrically switchable glass.

FIG. 7 is a diagram illustrating performing visible light communication by using sunlight or atmospheric light as a light source and using a visible light communication device using electrically switchable glass according to an embodiment of the present invention.

Referring to FIG. 7, a light source 710 exists outside, and visible light output from the light source 710 passes through electrically switchable glass installed between walls.

At this time, the control unit 720 can adjust the transmittance of the electrically switchable glass based on the data signal, and thus, the visible light output from the light source 710 is adjusted in brightness corresponding to the data signal, and the modulated signal ( 740).

At this time, the modulated signal 740 reaches the light receiver 750, is demodulated inside the light receiver 750, is converted back into a data signal, and can receive a data signal.

In this case, there is no limitation on the type of the light source 710. Visible light communication can be performed using not only incandescent light bulbs, fluorescent lamps, and LED light bulbs used in the past, but also visible light output from the sun or outdoor light (such as street lights, security lights, and landscape lights).

As shown in FIG. 7, the visible light communication device using electrically switchable glass according to an embodiment of the present invention can also be used in the form of a window.

8 is a flowchart illustrating a visible light communication method using an electrically switchable glass according to an embodiment of the present invention.

Referring to FIG. 8, first, a data signal is received (S810).

In addition, current and voltage corresponding to the data signal are generated, and the transmittance of the electrically switchable glass is controlled based on the current and voltage (S820).

In this case, the data signal received in step S810 is converted to generate a transmission signal, and the transmittance of the electrically switchable glass may be controlled using the transmission signal.

In this case, the transmittance of the electrically switchable glass may be controlled based on changes in current and voltage by performing switching using a switchable circuit unit.

For example, when the data signal 1 is transmitted to the switchable circuit unit, the digital signal 0 may be in the state, and when the data signal 0 is transmitted, the digital signal 1 may be in the state. Accordingly, whether a current flows through the switchable circuit unit may be determined according to whether the data signal is 1 or 0, and the transmittance of the electrically switchable glass may be changed according to whether a current flows through the switchable circuit unit.

Further, for example, when the data signal 0 is transmitted to the switchable circuit unit, the digital signal 0 may be in the state, and when the data signal 1 is transmitted, the digital signal 1 may be in the state. Accordingly, whether a current flows through the switchable arc unit may be determined depending on whether the data signal is 1 or 0, and the transmittance of the electrically switchable glass may change depending on whether a current flows through the switchable circuit unit.

In this case, the state of the digital signal 0 may mean transmitting visible light having a lower illuminance than the state of the digital signal 1. For example, the digital signal 0 state means a state in which all visible light is blocked and visible light cannot be received, and the digital signal 1 state means a state in which all visible light is transmitted and visible light is received.

Also, for example, the digital signal 0 state means a state in which visible light can be transmitted below a specific threshold, and the digital signal 1 state means a state in which visible light can be transmitted above a specific threshold.

In this case, the transmittance of the glass may be controlled in consideration of the surrounding brightness. For example, when the surroundings are bright due to a light source output from other light sources, when transmitting the data signal 1, the transmittance may be made larger than before to increase the intensity of visible light used for performing visible light communication. In addition, for example, when the surrounding is dark, when transmitting the data signal 0, the transmittance may be made smaller than the existing sea, so that the intensity of visible light used for performing visible light communication may be lowered. This is because when the surroundings are dark, there is no problem in performing visible light communication even if the intensity of visible light is reduced. Rather, if the intensity of visible light is not lowered, it may cause discomfort to people's eyes, so it may be more desirable to lower the intensity of visible light.

In addition, the brightness of visible light passing through the glass is adjusted based on the transmittance (S830), and visible light communication is performed using the visible light passing through the glass (S840).

In this case, the meaning of controlling the brightness of visible light based on the transmittance means that the more visible light passes, the brighter the visible light becomes, and the more visible light does not pass, the darker the brightness of the visible light.

At this time, when there is visible light passing through the glass, the receiver that receives visible light generates digital signal 1, and when there is no visible light that has passed through the glass, the receiver that does not receive visible light generates digital signal 0 Visible light communication can be performed by using the method.

Visible light using the electrically switchable glass according to the present invention as described above

The communication device and method are not limited to the configuration and method of the embodiments described as described above, but the embodiments are configured by selectively combining all or part of each embodiment so that various modifications can be made. May be.

110, 210: switchable circuit unit
520: control unit
610: power control unit
611, 612: power line
620, 710: light source
630, 730: electrically switchable glass
640, 721: control unit
650, 740: modulated signal
660, 750: receiver

Claims (17)

delete A receiver for receiving a data signal;
A control unit for generating a current and voltage corresponding to the data signal and controlling the transmittance of the electrically switchable glass based on the current and voltage; And
A transmitter that adjusts the brightness of visible light passing through the glass based on the transmittance, and performs visible light communication using the visible light passing through the glass
Including,
The control unit
A code data generator configured to generate code data by converting the data signal based on a preset rule;
A modulator that modulates the code data to generate a transmission signal corresponding to the data signal; And
Switchable circuit unit for controlling the flow of current and voltage corresponding to the transmission signal by performing switching based on the transmission signal
Visible light communication device using an electrically switchable glass comprising a. The method according to claim 2,
The electrically switchable glass is
Visible light communication device using an electrically switchable glass, characterized in that the transmittance is controlled based on whether current and voltage change in the switchable circuit unit. The method of claim 3,
The switchable circuit unit is
A visible light communication device using an electrically switchable glass, characterized in that the switching is performed based on the transmission signal, and as a result of the execution, the state becomes any one of a digital logic 0 state and a digital logic 1 state. The method of claim 4,
The electrically switchable glass is
Visible light communication device using electrically switchable glass, characterized in that the transmittance is lowest when the digital logic is in the 0 state and the transmittance is highest when the digital logic is in the 1 state. The method of claim 4,
The electrically switchable glass is
Visible light communication device using electrically switchable glass, characterized in that the transmittance is highest when in the digital logic 0 state and the transmittance is lowest in the digital logic 1 state. The method of claim 4,
The control unit
A power control unit for transferring power to the electrically switchable glass, the code data generation unit, the modulation unit, and the switchable circuit unit;
Visible light communication device using an electrically switchable glass, characterized in that it further comprises. The method of claim 5,
The switchable circuit unit is
When the transmission signal corresponds to the data signal 0, the digital logic 0 state, when the transmission signal corresponds to the data signal 1, the electronically switchable glass, characterized in that the digital logic 1 state Visible light communication device used. The method of claim 6,
The switchable circuit unit is
When the transmission signal corresponds to the data signal 1, the digital logic 0 state, when the transmission signal corresponds to the data signal 0, the electronically switchable glass, characterized in that the digital logic 1 state Visible light communication device used. delete Receiving a data signal;
Generating a current and voltage corresponding to the data signal, and controlling the transmittance of the electrically switchable glass based on the current and voltage; And
Adjusting the brightness of visible light passing through the glass based on the transmittance, and performing visible light communication using the visible light passing through the glass
Including,
The step of controlling the transmittance is
Generating code data by converting the data signal based on a preset rule;
Generating a transmission signal corresponding to the data signal by modulating the code data; And
And controlling a flow of a current and a voltage corresponding to the transmission signal by performing switching by a switchable circuit unit based on the transmission signal. The method of claim 11,
The electrically switchable glass is
Visible light communication method using an electrically switchable glass, characterized in that the transmittance is controlled based on whether current and voltage are changed in the switchable circuit unit. The method of claim 12,
The step of controlling the flow of current
The visible light communication method using the electrically switchable glass, characterized in that the switching is performed based on the transmission signal, and as a result of the execution, the switchable circuit unit enters any one of a digital logic 0 state and a digital logic 1 state. The method of claim 13,
The electrically switchable glass is
In the digital logic 0 state, the transmittance is the lowest, and when the digital logic 1 state, the transmittance is the highest. Visible light communication method using electrically switchable glass. The method of claim 13,
The electrically switchable glass is
In the digital logic 0 state, the transmittance is highest, and when the digital logic 1 state, the transmittance is lowest. The method of claim 14,
Controlling the flow of current corresponding to the transmission signal
When the transmission signal corresponds to the data signal 0, the state of the switchable circuit unit becomes the digital logic 0 state, and when the transmission signal corresponds to the data signal 1, the state of the switchable circuit unit is Visible light communication method using electrically switchable glass, characterized in that the digital logic 1 state. The method of claim 15,
Controlling the flow of current corresponding to the transmission signal
When the transmission signal corresponds to the data signal 0, the switchable circuit unit enters the digital logic 1 state, and when the transmission signal corresponds to the data signal 1, the switchable circuit unit corresponds to the digital logic 0 Visible light communication method using an electrically switchable glass, characterized in that in the state.

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